/*=========================================================================

  Program:   Visualization Toolkit
  Module:    TestImageDataInterpolation.cxx

  Copyright (c) Ken Martin, Will Schroeder, Bill Lorensen
  All rights reserved.
  See Copyright.txt or http://www.kitware.com/Copyright.htm for details.

     This software is distributed WITHOUT ANY WARRANTY; without even
     the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR
     PURPOSE.  See the above copyright notice for more information.

=========================================================================*/
// .NAME TestImageDataInterpolation.cxx -- Test interpolation from image data
//
// .SECTION Description
//  This test applies a function, F(x,y,z), to the image data and tests the
//  interpolation.

#include "vtkCell.h"
#include "vtkDebugLeaks.h"
#include "vtkDoubleArray.h"
#include "vtkIdList.h"
#include "vtkImageData.h"
#include "vtkPointData.h"
#include "vtkPoints.h"
#include "vtkSmartPointer.h"

#include <cassert>
#include <cmath>
#include <limits>

// Description:
// Performs safe division a/b which also checks for underflow & overflow
double SafeDiv(const double a, const double b)
{
  // Catch overflow
  if ((b < 1) && (a > (b * std::numeric_limits<double>::max())))
    return std::numeric_limits<double>::max();

  // Catch underflow
  if ((a == static_cast<double>(0.0)) || ((b > 1) && (a < b * std::numeric_limits<double>::max())))
    return (static_cast<double>(0.0));

  return (a / b);
}

// Description:
// Checks if two given floating numbers are equivalent.
// This algorithm is based on Knuth, The of Computer Programming (vol II).
bool eq(double a, double b, double TOL = 1e-9)
{
  double adiff = std::abs(a - b);
  double d1 = SafeDiv(adiff, std::abs(a));
  double d2 = SafeDiv(adiff, std::abs(b));
  if ((d1 <= TOL) || (d2 <= TOL))
    return true;
  return false;
}

// Description:
// Applies the function to the point with the given coordinates.
// The function is defined as F(x,y,z)= x + y + z
inline double F(const double x, const double y, const double z)
{
  return ((x + y + z));
}

// Description:
// Returns the grid with the specified extent, origin and spacing.
inline vtkImageData* GetGrid(int dims[3], double origin[3], double h[3])
{
  vtkImageData* image = vtkImageData::New();
  assert("pre: image data is nullptr!" && (image != nullptr));

  image->SetDimensions(dims);
  image->SetOrigin(origin);
  image->SetSpacing(h);

  vtkPointData* PD = image->GetPointData();
  assert("pre: point-data is nullptr" && (PD != nullptr));

  vtkDoubleArray* dataArray = vtkDoubleArray::New();
  dataArray->SetName("Fx");
  dataArray->SetNumberOfTuples(image->GetNumberOfPoints());
  dataArray->SetNumberOfComponents(1);

  vtkIdType idx = 0;
  for (; idx < image->GetNumberOfPoints(); ++idx)
  {
    double pnt[3];
    image->GetPoint(idx, pnt);
    dataArray->SetComponent(idx, 0, F(pnt[0], pnt[1], pnt[2]));
  } // END for all points

  PD->AddArray(dataArray);
  dataArray->Delete();

  return (image);
}

// Description:
// Given the image data this method returns a list of test points for
// interpolation at each cell center.
inline vtkPoints* GetReceivePoints(vtkImageData* img, vtkIdList* donorCellList)
{
  vtkPoints* rcvPoints = vtkPoints::New();
  rcvPoints->SetNumberOfPoints(img->GetNumberOfCells());
  donorCellList->SetNumberOfIds(img->GetNumberOfCells());

  vtkIdType cellIdx = 0;
  for (; cellIdx < img->GetNumberOfCells(); ++cellIdx)
  {
    // Get cell
    vtkCell* myCell = img->GetCell(cellIdx);
    assert("pre: myCell != nullptr" && (myCell != nullptr));

    // Compute center
    double c[3];
    double pCenter[3];
    double* weights = new double[myCell->GetNumberOfPoints()];
    int subId = myCell->GetParametricCenter(pCenter);
    myCell->EvaluateLocation(subId, pCenter, c, weights);
    delete[] weights;

    // Insert center to point list
    donorCellList->SetId(cellIdx, cellIdx);
    rcvPoints->SetPoint(cellIdx, c);
  } // END for all cells

  return (rcvPoints);
}

// Description:
// Given the mesh data, the donor cell and the interpolation weights, this
// method returns the interpolated value at the corresponding point location.
inline double InterpolateValue(vtkImageData* img, vtkCell* c, double* w)
{
  assert("pre: image is nullptr!" && (img != nullptr));
  assert("pre: donor cell is nullptr" && (c != nullptr));
  assert("pre: weights is nullptr" && (w != nullptr));

  vtkPointData* PD = img->GetPointData();
  assert("pre: point data is nullptr" && (PD != nullptr));
  vtkDataArray* dataArray = PD->GetArray("Fx");
  assert("pre: data array is nullptr" && (dataArray != nullptr));

  std::cout << "W:[";
  std::cout.flush();
  double val = 0.0;
  vtkIdType numNodes = c->GetNumberOfPoints();
  for (vtkIdType nodeIdx = 0; nodeIdx < numNodes; ++nodeIdx)
  {
    std::cout << w[nodeIdx] << " ";
    std::cout.flush();
    vtkIdType meshNodeIdx = c->GetPointId(nodeIdx);
    val += w[nodeIdx] * dataArray->GetComponent(meshNodeIdx, 0);
  } // END for all cells nodes
  std::cout << "]\n";
  std::cout.flush();
  return (val);
}

// Description:
// Main test routine for testing the interpolation
inline int TestInterpolation(int dims[3], double origin[3], double h[3])
{
  vtkImageData* grid = GetGrid(dims, origin, h);
  assert("pre: grid is nullptr" && (grid != nullptr));

  std::cout << "NUMBER OF CELLS:  " << grid->GetNumberOfCells() << std::endl;
  std::cout.flush();

  vtkIdList* donors = vtkIdList::New();
  vtkPoints* pnts = GetReceivePoints(grid, donors);

  int subId = 0;
  double pcoords[3];
  double weights[8];
  double x[3];

  int interpErrors = 0;

  vtkIdType idx = 0;
  for (; idx < pnts->GetNumberOfPoints(); ++idx)
  {
    pnts->GetPoint(idx, x);
    vtkIdType cellIdx = grid->FindCell(x, nullptr, 0, 0.0, subId, pcoords, weights);

    if (cellIdx < 0)
    {
      std::cerr << "point (" << x[0] << ", " << x[1] << ", " << x[2];
      std::cerr << ") is out-of-bounds!\n";
      return 1;
    }

    vtkCell* donorCell = grid->GetCell(cellIdx);
    assert("pre: donor cell is nullptr" && (donorCell != nullptr));

    std::cout << "N:  [" << pcoords[0] << " ";
    std::cout << pcoords[1] << " " << pcoords[2] << "]\n";
    std::cout.flush();

    double f = InterpolateValue(grid, donorCell, weights);
    double fExpected = F(x[0], x[1], x[2]);

    if (!eq(f, fExpected))
    {
      std::cout << "INTERPOLATION ERROR: ";
      std::cout << "f_expeted=" << fExpected << " ";
      std::cout << "f_interp=" << f << std::endl;
      std::cout.flush();
      ++interpErrors;
    }

  } // END for all points

  grid->Delete();
  donors->Delete();
  pnts->Delete();

  return interpErrors;
}

// Description:
// Test main function
int TestImageDataInterpolation(int, char*[])
{
  static int dims[4][3] = {
    { 3, 3, 1 }, // XY Plane
    { 3, 1, 3 }, // XZ Plane
    { 1, 3, 3 }, // YZ Plane
    { 3, 3, 3 }  // XYZ Volume
  };

  static const char* TestName[4] = { "XY-Plane", "XZ-Plane", "YZ-Plane", "XYZ-Grid" };

  double origin[3];
  origin[0] = origin[1] = origin[2] = 0.0;

  double h[3];
  h[0] = h[1] = h[2] = 0.2;

  int testStatus = 0;
  for (int i = 0; i < 4; ++i)
  {
    std::cout << "Testing " << TestName[i] << "...\n";
    std::cout.flush();
    int rc = 0;
    rc = TestInterpolation(dims[i], origin, h);
    testStatus += rc;
    std::cout << "[DONE]\n";
    std::cout.flush();

    if (rc != 0)
    {
      std::cout << rc << " failures detected!\n";
      std::cout << "TEST FAILED!\n\n";
      std::cout.flush();
    }
    else
    {
      std::cout << "TEST PASSED!\n";
      std::cout << std::endl;
    }
  } // END for all tests

  return (testStatus);
}
